Infrared Observations of Nebular Emission Lines from Galaxies atz≃ 3

Abstract

We present the first results from a program of near-infrared spectroscopy aimed at studying the familiar rest-frame optical emission lines from the H II regions of Lyman break galaxies at z 3. By targeting redshifts that bring the lines of interest into gaps between the strong OH sky emission, we have been successful in detecting Balmer and [O III] emission lines in all five galaxies observed so far with CGS4 on UKIRT. The typical line fluxes are a few times 10-17 ergs s-1 cm-2, approximately 1 order of magnitude lower than the limits reached with wide-field narrowband imaging surveys. For a Salpeter initial mass function and a H0 = 70 km s-1 Mpc-1, q0 = 0.1 cosmology, the Hβ luminosities uncorrected for dust extinction imply star formation rates of 20-270 M☉ yr-1; these values are greater than those that may have been deduced from the ultraviolet continuum luminosities at 1500 A by factors of between ~0.7 and ~7. Uncertainties in the shape of the reddening curve and in the intrinsic UV continuum slope do not yet allow us to assess accurately the level of dust extinction; however, on the basis of the present limited sample, it appears that an extinction of 1-2 mag at 1500 A may be typical of Lyman break galaxies. This value is consistent with recent estimates of dust obscuration in star-forming galaxies at z ≤ 1 and does not require a substantial revision of the broad picture of star formation over the Hubble time proposed by Madau and coworkers in 1996. In four out of five cases the velocity dispersion of the emission line gas is σ 70 km s-1, while in the fifth the line widths are nearly three times larger. Virial masses Mvir ≈ (1-5) × 1010 M☉ are suggested, but both velocities and masses could be higher, because our observations are only sensitive to the brightest cores of these systems where the line widths may not sample the full gravitational potential. The relative redshifts of interstellar absorption, nebular emission, and Lyα emission lines differ by several hundred km s-1 and suggest that large-scale outflows may be a common characteristic of Lyman break galaxies. The forthcoming availability of high-resolution infrared spectrographs on large telescopes will soon allow all of these questions to be addressed in much greater detail.